US7301651B2 - Information processor, printing apparatus, information processing system, printing method and printing program - Google Patents

Information processor, printing apparatus, information processing system, printing method and printing program Download PDF

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US7301651B2
US7301651B2 US09/968,011 US96801101A US7301651B2 US 7301651 B2 US7301651 B2 US 7301651B2 US 96801101 A US96801101 A US 96801101A US 7301651 B2 US7301651 B2 US 7301651B2
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printing
printing apparatus
command
output
print data
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US20020041389A1 (en
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Akihiko Noda
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Canon Inc
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Canon Inc
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    • GPHYSICS
    • G06COMPUTING OR CALCULATING; COUNTING
    • G06KGRAPHICAL DATA READING; PRESENTATION OF DATA; RECORD CARRIERS; HANDLING RECORD CARRIERS
    • G06K15/00Arrangements for producing a permanent visual presentation of the output data, e.g. computer output printers
    • G06K15/02Arrangements for producing a permanent visual presentation of the output data, e.g. computer output printers using printers
    • G06K15/12Arrangements for producing a permanent visual presentation of the output data, e.g. computer output printers using printers by photographic printing, e.g. by laser printers

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  • the present invention relates to a printing system constituted by a host unit and a print output apparatus for performing printing of print data supplied from the host unit.
  • print output apparatuses in information processing systems form images by fixing toner, ink or the like on paper, etc.
  • a printer print output apparatuses
  • laser beam printers and copying machines have a mechanism for fixing toner on paper by heating a thermal transfer drum portion.
  • Some laser beam printers require electric power of, for example, about 765 W for printing (heating). Such high electric power is required because of the need to heat the thermal transfer drum portion to a high temperature and to rapidly heat the drum to a temperature at which printing can be performed. If the heating time period is reduced, the time period taken to start printing is reduced. That is, it is possible to increase the overall printing speed by reducing the heating time period.
  • a technique has therefore been used in a printer which sets a printer in a standby state in which the thermal transfer drum portion is constantly maintained at a temperature close to the high temperature at which printing can be performed.
  • the technique enables the printer to start printing immediately after receiving the print data and to always perform high-speed printing if the frequency of use of the printer is high.
  • the frequency of use of the printer is low, a large amount of electric power consumed in the standby state (e.g., about 183 W) is wasted.
  • a technique has been used in many printers which sets the state of the printer to be shifted from the standby state to a sleep state in which power consumption is automatically limited in the case where the printer is maintained in the standby state without being used during certain time period. More specifically, when the printer is shifted to the sleep state, the temperature at which the thermal transfer drum portion is kept is reduced or the heat-retention is stopped.
  • the power consumption in the sleep state is about 22 W and there is an effect of reducing the power consumption by 161 W compared to that of the standby state.
  • a technique has also been used which automatically performs processing for shifting to the standby state, including heating the thermal transfer drum portion, when the print data is received in the sleep state.
  • the conventional printers are designed so as to operate selectively in the standby state or the sleep state, thereby achieving both high-speed printing in a situation where the frequency of use is high and an economical effect in a situation where the frequency of use is low.
  • FIGS. 12A , 12 B, 13 A, and 13 B A situation where such a problem arises will be described in detail with reference to FIGS. 12A , 12 B, 13 A, and 13 B.
  • a printing system has a host computer and a printer connected to each other in a one-to-one relationship, for example. If the printer is a machine for black-and-white (B/W) printing, a printing process started by the host computer when the printer is in the standby state is performed as shown in FIG. 12A .
  • B/W black-and-white
  • a user makes the host computer display a dialog box of software (a printer driver or the like) as shown in FIG. 4 to the print data according to his or her need.
  • the time taken to complete print setting through this dialog box is assumed to be 30 seconds.
  • This print setting comprises designating the printer to be used, print attributes (color/black-and-white, a paper size, a paper ejection port, a paper feed port, etc.), and a print style and details of the style (simplex/duplex print, N-up print, binding margins, etc.).
  • the printer driver thereafter receives drawing data from an application, converts the drawing data into the print data obtained as a printable material, and successively sends the print data to the printer.
  • the time taken to complete this print data preparation and transfer is assumed to be 45 seconds.
  • the printer starts receiving the print data 35 seconds after the moment at which the printer driver starts processing, and that the time taken to complete printing (which ends by completing paper ejection) in the printer is 35 seconds.
  • the time period from the moment at which the user starts the printing operation to the moment at which an output sheet is ejected is 100 seconds, as shown in FIG. 12A .
  • the printing process using the same data in the B/W printer is started by the host computer when the printer is in the sleep state, the printing process is performed as shown in FIG. 12B .
  • 20 seconds are taken to complete state-shift processing, i.e., heating the thermal transfer drum.
  • the time period from the moment at which the user starts the printing operation to the moment at which an output sheet is ejected is 120 seconds, as shown in FIG. 12B . That is, the speed of printing from the sleep state is reduced by 20 seconds compared to that of printing started from the standby state.
  • processing for shifting from the sleep state to the standby state may include calibration processing which is correction processing for improving the quality of images in color and the reproducibility of colors. That is, a phenomenon occurs in which the quality of a visible image formed by the printer is reduced due to electrical and mechanical causes in the process of forming the visible image, which are, in most cases, environmental changes and wear of each component of the printer.
  • calibration processing which is correction processing for improving the quality of images in color and the reproducibility of colors. That is, a phenomenon occurs in which the quality of a visible image formed by the printer is reduced due to electrical and mechanical causes in the process of forming the visible image, which are, in most cases, environmental changes and wear of each component of the printer.
  • a technique has been used which improves the image quality by using a density measuring sensor, etc., provided in the printer, by preparing suitable correction data, and by preparing the print data in which the correction data is reflected.
  • the printing process started by the host when the printer is in the standby state includes no state-shift processing, and requires 100 seconds as the time period from the moment at which the user starts the printing operation to the moment at which an output sheet is ejected, as shown in FIG. 13A .
  • the printing process using the same data and started by the host when the color printer is in the sleep state is performed as shown in FIG. 13B .
  • the printer starts receiving the print data 35 seconds after the moment at which the printer driver starts processing, heating of the thermal transfer drum portion is then started and continued for 20 seconds, and 90 seconds are taken before the completion of calibration processing. That is, 110 seconds are taken for state-shift processing.
  • the time period from the moment at which the user starts the printing operation to the moment at which an output sheet is ejected is 210 seconds, as shown in FIG. 13B . That is, the speed of printing from the sleep state is reduced by 110 seconds compared to that of printing started from the standby state.
  • the present invention has been made in view of the above-described problem of the conventional art, and an object of the present invention is therefore to provide a print output apparatus, etc., capable of effectively increasing the printing speed even when printing is started from the sleep state.
  • FIG. 1 is a block diagram showing the configuration of an information processing system relating to a first embodiment of the present invention
  • FIG. 2 is a block diagram showing the internal configurations of a host and a printer shown in FIG. 1 ;
  • FIG. 3 is a flowchart showing processing in a host computer 10 ;
  • FIG. 4 is a diagram showing an example of a display of a print dialog box
  • FIG. 5 is a flowchart showing processing in a printer 20 ;
  • FIG. 6 is a timing chart of the printing operation of the first embodiment
  • FIGS. 7A and 7B are timing charts of the printing operation of an information processing system in a second embodiment of the present invention.
  • FIG. 8 is a block diagram showing another example of the form of connection between a host and a printer in accordance with the present invention.
  • FIG. 9 is a diagram schematically showing a state where modules in which the present invention is realized and related data are loaded from a memory medium reader into the host to be executed or used;
  • FIG. 10 is a diagram showing modules in accordance with the present invention and related data recorded on a memory medium
  • FIG. 11 is a diagram showing a memory map of the modules in accordance with the present invention in a state where the modules are made executable by being loaded into a RAM in a memory section of the host;
  • FIGS. 12A and 12B are timing charts of the printing operation of a conventional information processing system.
  • FIGS. 13A and 13B are timing charts of the printing operation of another conventional information processing system.
  • FIG. 1 is a block diagram showing the configuration of an information processing system relating to a first embodiment of the present invention.
  • FIG. 2 is a block diagram showing the internal configurations of a host and a printer shown in FIG. 1 .
  • This information processing system is formed by connecting a host computer 10 and a printer 20 in a one-to-one relationship.
  • the host computer 10 is capable of providing a state-shift instruction to the printer 20
  • the printer 20 has the function of state-shift processing according to the instruction from the host computer 10 .
  • the host computer 10 is constituted by a controller 1010 , a connector 1020 , a memory section 1030 , a display 1040 , a memory medium reader 1050 , a memory medium 1060 , and an input section 1070 .
  • the printer 20 is constituted by a controller 2010 , a connector 2020 , a memory section 2030 , and a print section 2040 .
  • the host computer 10 is formed by a personal computer, a workstation, a minicomputer or the like.
  • Each of the connectors 1020 and 2020 is constituted by a serial interface board, a parallel interface board, a network interface board or the like.
  • Each of the memory sections 1030 and 2030 is constituted by memory devices, and a magnetic disk unit, a magneto-optical disc unit, a magnetic tape unit or the like.
  • the print section 2040 is of a laser beam type, a bubble jet type, a light emitting diode (LED) type, or a thermal transfer type.
  • the display 1040 is a cathode ray tube (CRT), a liquid crystal display or the like.
  • the input section 1070 is constituted by a keyboard and a mouse, a track ball or the like.
  • the memory medium reader 1050 is constituted by a floppy disk (FD) unit, a magneto-optical (MO) unit, a compact disc-read only memory (CD-ROM) unit, an IC memory card unit or the like.
  • the memory medium 1060 is a hard disk (HD), an MO disc, a CD-ROM, an IC memory card or the like.
  • the printer 20 may be replaced with a plotter, a copying machine, a facsimile machine or the like.
  • Each of the controllers 1010 and 2010 may be constituted by a software, a read-only memory (ROM), a random access memory (RAM), etc.
  • the printer 20 is a B/W machine in a sleep state and printer information (information about B/W machine) is stored in a RAM in the memory section 1030 of the host computer 10 .
  • FIG. 3 is a flowchart showing processing on the host computer 10 side
  • FIG. 4 is a diagram showing an example of a display of a printing dialog
  • FIG. 5 is a flowchart showing processing on the printer 20 side
  • FIG. 6 is a timing chart showing the printing process in the first embodiment.
  • a user performs print setting through the host computer 10 by displaying a print dialog box ( FIG. 4 ) of a software (a printer driver or the like) for preparing the print data (step S 101 in FIG. 3 ), and the controller 1010 immediately sends a command “standby” for shifting from the sleep state to the standby state to the printer 20 (step S 102 ).
  • a print dialog box FIG. 4
  • a software a printer driver or the like
  • the controller 1010 sends a command “standby” to the controller 2010 of the printer 20 via the connector 1020 of the host computer 10 and the connector 2020 of the printer 20 .
  • the controller 2010 of the printer 20 temporarily stores the command received in the RAM of the memory section 2030 .
  • the command “standby” may be sent to the printer 20 via a server.
  • the controller 2010 of the printer 20 makes a determination as to whether any print data has been received from the host computer 10 (step S 201 in FIG. 5 ). If the controller 2010 determines that some print data has been received, it temporarily stores the received print data in the RAM of the memory section 2030 (step S 202 ). Since in this example the host computer 10 has transmitted no print data to the printer 20 , the controller 2010 of the printer 20 determines that no print data has been received.
  • the controller 2010 of the printer 20 checks the contents of the RAM of the memory section 2030 and makes a determination as to whether any print data exists (step S 203 ). If the controller 2010 determines that some print data exists, it then makes a determination as to whether the printer is presently in the sleep state or not (step S 204 ). Since in this example no print data is stored, the controller 2010 of the printer 20 determines that no print data exists.
  • the controller 2010 of the printer 20 checks the contents of the RAM of the memory section 2030 and makes a determination as to whether any command has been received (step S 210 ). If the controller 2010 determines that no command has been received, it returns the process to step S 201 . Since in this example the command has been sent from the host computer 10 in step S 102 and stored in the printer 20 , the controller 2010 of the printer 20 determines that the command has been received.
  • the controller 2010 of the printer 20 checks the contents of the RAM of the memory section 2030 to recognize the content of a command (step S 211 ), and makes, from the result of checking in step S 211 , a determination as to whether the content of the command is “standby” (step S 212 ). If the content of the command is other than “standby”, the controller 2010 makes a determination from the result of step S 211 as to whether the content of the command is “calibration off” (step S 216 ).
  • the content of the command is other than “calibration off” and the controller 2010 executes processing according to the content of the command (step S 213 ). For example, if the command is provided as an inquiry about the size of paper loaded in the printer 20 , the controller 2010 sends information such as “A4”, “A3” or “B4” back to the host computer 10 . Since in this example the command sent from the host computer 10 in step S 102 is “standby”, the controller 2010 of the printer 20 determines that the content of the command is “standby” in step S 212 .
  • the controller 2010 of the printer 20 then makes a determination as to whether the printer is presently in the sleep state (step S 214 ). If the printer is not in the sleep state, the controller 2010 returns the process to step S 201 . Since in this example the printer 20 is in the sleep state, the controller 2010 starts processing for shifting from the sleep state to the standby state, the printer entering a shifting state (step S 215 ). The process then returns to step S 201 .
  • the processing time from execution of step S 101 in the host computer 10 to execution of step S 215 in the printer 20 is assumed to be 5 seconds. That is, as shown in FIG. 6 , 5 seconds after the moment at which the dialog box is displayed as a start of the printing operation by the user, shift processing is started in the printer 20 .
  • the processing time assumed to be 5 seconds in this embodiment varies depending on the connection form, the throughputs of the computer 10 and the printer 20 , and other environmental conditions. Since the printer 20 is assumed to be a B/W machine, only heating is performed as shift processing. A time of 20 seconds is taken to heat the thermal transfer drum portion of the printer 20 , and the time period from the moment at which the user displays the dialog box as a start of the printing operation to the moment at which shift processing is completed is 25 seconds. The printer then enters the standby state and starts printing if some print data exists.
  • the controller 1010 of the host computer 10 makes a determination as to whether the user has performed print setting through the input section 1070 (step S 103 in FIG. 3 ). Since in this example the controller 1010 makes this determination immediately after opening of the dialog box, it determines that the user has not performed print setting. The controller 1010 then makes a determination as to whether the user has pressed a print button through the input section 1070 (step S 105 ). Since in this example the controller 1010 makes this determination immediately after opening of the dialog box, it determines that the user has not pressed the print button and returns the process to step S 103 .
  • steps 103 to S 105 are repeated. It is assumed here that at a certain point of time, the user performs print setting comprising designating the name of the printer 20 for outputting, print attributes (B/W, a paper size of A4, an upper portion of the printer body as a paper ejection port, and an upper cassette as a paper feed port), and a print style and details of the style (simplex print, and binding margins) through the input section 1070 .
  • the controller 1010 determines in step S 103 that print settings have been selected, and stores information on the settings in the RAM of the memory section 1030 (step S 104 ), which is to be referred to when the print data is prepared afterwards.
  • the controller 1010 determines in step S 105 that the print button is pressed.
  • the time period from the moment at which the user displays the dialog box as a start of the printing operation to the moment at which the user presses the print button after print setting is assumed to be 30 seconds, as shown in FIG. 6 .
  • the printer 20 since the time period from the moment at which the user displays the dialog box as a start of the printing operation to the moment at which shift processing is completed is 25 seconds, the printer 20 is set in the standby state at least 5 seconds before the time when the print data is transmitted from the host computer 10 . That is, the print environment is such that, even though the printer 20 is in the sleep state when the printing operation is started, preparation and transfer of the print data can be performed in the same way as in the case of printing from the standby state.
  • the controller 1010 refers to the printer 20 information and print attribute information stored in the RAM of the memory section 1030 of the host computer 10 , and makes a determination as to whether the printer 20 for outputting is a color machine and whether a B/W output setting has been selected (step S 109 ). Since in this example the printer is a B/W machine and since a B/W print setting has been selected, the process advances to step S 106 .
  • the controller 1010 then prepares a portion of the print data by receiving a portion of drawing data from an application, temporarily stores the prepared data in the RAM of the memory section 1030 of the host computer 10 (step S 106 ), and sends to the printer 20 the print data portion temporarily stored in the RAM of the memory section 1030 (step S 107 ). More specifically, the controller 1010 transfers the print data portion to the controller 2010 of the printer 20 via the connector 1020 of the host computer 10 and the connector 2020 of the printer 20 .
  • the controller 2010 of the printer 20 makes a determination as to whether any print data has been received from the host computer 10 (step S 201 ). Since in this example the print data portion has been transmitted to the printer 20 from the host computer 10 in step S 107 , the controller 2010 of the printer 20 determines in step S 201 that the print data has been received from the host computer 10 .
  • the controller 2010 of the printer 20 temporarily stores the received print data in the RAM of the memory section 2030 (step S 202 ). Further, the controller 2010 checks the contents of the RAM of the memory section 2030 and makes a determination as to whether any print data exists therein (step S 203 ). Since in this example the transmitted print data portion has been stored in step S 202 , the controller 2010 of the printer 20 determines that the print data exists.
  • step S 204 the controller 2010 of the printer 20 makes a determination as to whether the printer 20 is presently in the sleep state. Since in this example step S 215 in the printer 20 has been executed in step S 102 in the host computer 10 to complete shift processing and to set the printer 20 in the standby state, the controller 2010 determines that the printer 20 is not in the sleep state.
  • the controller 2010 of the printer 20 makes a determination as to whether the printer 20 is presently in the shifting state (step S 206 ). Since the printer 20 is in the standby state, the controller 2010 of the printer 20 determines that the printer 20 is not in the shifting state. The controller 2010 continues processing by referring to the print data stored in the RAM of the memory section 2030 (step S 207 ). The controller 2010 deletes the processed data (step S 208 ). The controller 2010 of the printer 20 then returns the process to step S 210 .
  • the controller 1010 checks the contents of the RAM of the memory section 1030 and makes a determination as to whether preparation and transfer of the print data are completed (step S 108 ). If the controller 1010 determines that preparation and transfer of the print data are completed, it ends the process. Since in this example preparation and transfer of the print data are not completed, the controller 1010 returns the process to step S 106 .
  • controller 1010 repeats steps S 106 to S 108 and ends the process when determining that preparation and transfer of the print data are completed.
  • the controller 2010 successively receives print data portions from the host computer 10 and repeats processing defined by the sequence of steps: steps S 201 , S 202 , S 203 , S 204 , S 206 , S 207 , S 208 , and S 210 , thereby completing printing of the print data received from the host computer 10 .
  • the state-shift command is sent from the host computer 10 to the printer 20 immediately after the time when the dialog box is displayed, thereby enabling shift processing to be executed before transmission of the print data. Consequently, even in the case where the printer 20 starts the printing process when it is in the sleep state, the time period from the moment at which the user starts the printing operation to the moment at which an output sheet is ejected is 100 seconds, equal to that in the case of starting the printing process when the printer is in the standby state, as shown in FIG. 6 .
  • a second embodiment of the present invention will be described, which has the same configurations as those shown in FIGS. 1 and 2 , and in which the printer 20 is a color machine in the sleep state. It is assumed here that information on the printer (color machine) is stored in the RAM of the memory section 1030 of the host computer 10 .
  • FIGS. 7A and 7B are timing charts showing the printing process performed by the information processing system of the second embodiment.
  • FIG. 7A shows the process with respect to color printing
  • FIG. 7B shows the process with respect to B/W printing.
  • the controller 1010 of the host computer 10 executes step S 102 in FIG. 3 to send a command “standby” for shifting from the sleep state to the standby state to the printer 20 , as it does in the operation with the B/W machine.
  • the controller 2010 of the printer 20 executes step S 215 in FIG. 5 to start processing for shifting from the sleep state to the standby state, thereby setting the printer 20 in the standby state.
  • the processing time from the moment at which step S 101 in the host computer 10 is executed to the moment at which step S 215 in the printer 20 is executed is assumed to be 5 seconds, as shown in FIG. 7A .
  • shift processing comprises heating and calibration processing by which shift processing is completed. That is, 20 seconds are taken to heat the thermal transfer drum portion of the printer 20 , and 90 seconds are thereafter taken for calibration processing. Consequently, the time period from the moment at which the user displays the dialog box as a start of the printing operation to the moment at which shift processing is completed is 115 seconds. The printer 10 then enters the standby state and starts printing if the print data exists.
  • Print setting is performed in steps S 103 to S 105 in the printer 20 for outputting, as is that in the B/W machine.
  • the time period from the moment at which the user displays the dialog box as a start of the printing operation to the moment at which the user presses the print button after print setting is assumed to be 30 seconds, as shown in FIG. 7B .
  • the printer 20 is in a state of performing shift processing (shifting state).
  • the controller 1010 of the host computer 10 makes a determination as to whether the printer 20 for outputting is a color machine and whether a B/W output setting has been selected by referring to the printer information and print attribute information stored in the RAM of the memory section 1030 (step S 109 ). Since in this example the printer 20 is a color machine and a color print setting has been selected, the process advances to step S 106 .
  • the controller 1010 prepares a portion of the print data by receiving a portion of drawing data from an application, temporarily stores the prepared data in the RAM of the memory section 1030 of the host computer 10 (step S 106 ).
  • the controller 1010 sends to the printer 20 the print data portion temporarily stored in the RAM of the memory section 1030 (step S 107 ). More specifically, the controller 1010 transfers the print data portion to the controller 2010 of the printer 20 via the connector 1020 of the host computer 10 and the connector 2020 of the printer 20 .
  • the controller 2010 of the printer 20 makes a determination as to whether any print data has been received from the host computer 10 (step S 201 ). Since in this example the print data portion has been transmitted to the printer 20 from the host computer 10 in step S 107 , the controller 2010 determines in step S 201 that the print data has been received from the host computer 10 .
  • the controller 2010 temporarily stores the received print data in the RAM of the memory section 2030 (step S 202 ). Further, the controller 2010 checks the contents of the RAM and makes a determination as to whether any print data exists therein (step S 203 ). Since in this example the transmitted print data portion has been stored in step S 202 , the controller 2010 of the printer 20 determines that the print data exists.
  • the controller 2010 makes a determination as to whether the printer 20 is presently in the sleep state (step S 204 ). Since in this example the printer 20 is in the shifting state, the controller 2010 of the printer 20 determines that the printer 20 is not in the sleep state. Further, the controller 2010 makes a determination as to whether the printer 20 is presently in the shifting state (step S 206 ). Since in this example the printer 20 is in the shifting state, the controller 2010 determines that the printer 20 is in the shifting state, and moves the process to step S 210 .
  • the controller 2010 temporarily stores each of the print data portions successively transmitted from the host computer 10 , since the printer 20 is in the shifting state while shift processing (complete calibration processing) is being executed. Steps S 106 to S 108 in the host computer 10 are repeatedly executed to complete transfer of the print data from the host computer 10 , as shown in FIG. 7A .
  • shift processing in the printer 20 is completed and printing (steps S 203 , S 204 , S 206 , S 207 , S 208 ) of the print data already transferred is immediately executed, thereby completing the process.
  • the shift-change command is sent from the host computer 10 to the printer 20 immediately after the display of the dialog box to enable shift processing to be started before a start of transfer of the print data.
  • the time period from the moment at which the user starts the printing operation to the moment at which an output sheet is ejected can be reduced by 60 seconds compared to that of the conventional art.
  • the controller 1010 executes step S 102 to send the command “standby” for shifting from the sleep state to the standby state to the printer 20 , as it does in the case of color printing in the color machine.
  • the controller 2010 of the printer 20 executes step S 215 to start processing for shifting from the sleep state to the standby state, thereby setting the printer 20 in the standby state.
  • the processing time from the moment at which step S 101 in the host computer 10 is executed to the moment at which step S 215 in the printer 20 is executed is assumed to be 5 seconds, as shown in FIG. 7B .
  • shift processing comprises heating and calibration processing by which shift processing is completed, as described above.
  • Print setting is performed in steps S 103 to S 105 in the printer 20 for outputting, as described above.
  • the time period from the moment at which the user displays the dialog box as a start of the printing operation to the moment at which the user presses the print button after print setting is assumed to be 30 seconds, as shown in FIG. 7A .
  • the printer 20 is in a state of performing shift processing (shifting state).
  • the controller 1010 of the host computer 10 makes a determination as to whether the printer 20 for outputting is a color machine and whether a B/W output setting has been selected by referring to the printer information and print attribute information stored in the RAM of the memory section 1030 (step S 109 ). Since in this example the printer 20 is a color machine and a B/W setting has been selected, the process advances to step S 110 .
  • the controller 1010 immediately sends to the printer 20 the command “calibration off” to stop calibration (step 110 ). More specifically, the controller 1010 sends the command “calibration off” to the controller 2010 of the printer 20 via the connector 1020 of the host computer 10 and the connector 2020 of the printer 20 . The controller 2010 of the printer 20 temporarily stores the received command in the RAM of the memory section 2030 . The command “calibration off” may be sent to the printer 20 via a server 40 . ⁇ Processing 2 in Printer 20 >
  • the controller 2010 of the printer 20 makes a determination as to whether any print data has been received from the host computer 10 (step S 201 ). If the controller 2010 determines that some print data has been received, it temporarily stores the received print data in the RAM of the memory section 2030 (step S 202 ). Since in this example the host computer 10 has transmitted no print data to the printer 20 , the controller 2010 determines that no print data has been received.
  • the controller 2010 checks the contents of the RAM of the memory section 2030 and makes a determination as to whether any print data exists (step S 203 ). Since in this example no print data is stored, the controller 2010 of the printer 20 determines that no print data exists. Further, the controller 2010 checks the contents of the RAM of the memory section 2030 and makes a determination as to whether any command has been received (step S 210 ). Since in this example the command has been sent from the host computer 10 in step S 110 and stored in the printer 20 , the controller 2010 determines that the command has been received.
  • the controller 2010 of the printer 20 checks the contents of the RAM of the memory section 2030 (step S 211 ) and makes, from the result of checking in step S 211 , a determination as to whether the content of the command is “standby” (step S 212 ). If the content of the command is other than “standby”, the controller 2010 makes a determination from the result of step S 211 as to whether the content of the command is “calibration off” (step S 216 ). Since in this example, the command sent from the host computer 10 in step S 110 is “calibration off”, the controller 2010 determines that the content of the command is “calibration off”.
  • the controller 2010 of the printer 20 checks the contents of the RAM of the memory section 2030 and makes a determination as to whether the printer 20 is in a state during calibration (step S 217 ). If the printer 20 is not in a state during calibration, the controller 2010 returns the process to step S 201 . Since in this example the printer 20 is in a state during calibration, the controller 2010 stops calibration processing (step S 218 ). The process then returns to step S 201 .
  • step S 218 In the example shown in FIG. 7B , calibration processing is assumed to be stopped 10 seconds after the moment at which it is started.
  • the printer 20 enters the standby state when calibration is stopped. Thereafter, the printer can start printing when receiving the print data.
  • the controller 1010 prepares a portion of the print data, temporarily stores the prepared data in the RAM of the memory section 1030 of the host computer 10 (step S 106 ), sends the stored print data portion to the printer 20 (step S 107 ), and makes a determination as to whether preparation and transfer of the print data are completed (step S 108 ), as it does in the above-described case. Since in this example preparation and transfer of the print data are not completed, it returns the process to step S 106 .
  • controller 1010 repeats steps S 106 to S 108 and ends the process when determining that preparation and transfer of the print data are completed.
  • the controller 2010 of the printer 20 makes a determination as to whether any print data has been received from the host computer 10 (step S 201 ). Since in this example the host computer 10 has transmitted the print data portion to the printer 20 , the controller 2010 of the printer 20 determines that the print data has been received from the host computer 10 .
  • the controller 2010 temporarily stores the received print data in the RAM of the memory section 2030 (step S 202 ) and makes a determination as to whether any print data exists (step S 203 ), as it does in the above-described case. Since in this example the transmitted print data portion is stored in step S 202 , the controller 2010 determines that the print data exists.
  • the controller 2010 makes a determination as to whether the printer 20 is in the sleep state (step S 204 ). Since in this example the printer 20 is in the standby state, the controller 2010 of the printer 20 determines that the printer 20 is not in the sleep state. The controller 2010 then makes a determination as to whether the printer 20 is in the shifting state (step S 206 ). Since in this example the printer 20 is in the standby state, the controller 2010 of the printer 20 determines that the printer 20 is not in the shifting state, and advances the process to step S 207 .
  • step S 207 the controller 2010 executes printing by referring to the print data stored in the RAM of the memory section 2030 , as it does in the above-described case.
  • the controller 2010 deletes the processed data (step S 208 ).
  • the controller 2010 checks the contents of the RAM of the memory section 2030 and makes a determination as to whether any command has been received (step S 210 ). Since in this example no command has been sent from the host computer 10 , the controller 2010 of the printer 20 determines that no command has been received, and returns the process to step S 201 .
  • each of the above-described first and second embodiments of the present invention has been described on the assumption that modules in which the present invention is realized are loaded in the disk unit in the memory section 1030 of the host computer 10 , and that the modules in which the present invention is realized are executed by being read to the RAM in the memory section 1030 of the host computer 10 when the host computer 10 is started.
  • each embodiment has been described on the assumption that modules in which the present invention is realized are loaded in the ROM in the memory section 2030 of the printer 20 , and that the modules are executed by being read to the RAM in the memory section 2030 of the printer 20 when the printer 20 is started.
  • the modules in which the present invention is realized are formed of program codes based on the flowchart shown in FIG. 3 or 5 .
  • connection between the host and the printer used in accordance with the present invention is not limited to the form in which the host and printer are connected in a one-to-one relationship as in each of the above-described embodiments.
  • the present invention can also be applied to, for example, a system as shown in FIG. 8 , in which a host and printers are connected to a print server.
  • a client 30 in the system shown in FIG. 8 is capable of obtaining an address (communication destination) of a printer (B) connected to a network even when it outputs data to the printer (B) via the server 40 .
  • the following are examples of means for obtaining this address.
  • the client 30 obtains address information by broadcasting through the network.
  • the client 30 obtains a printer address through an event such as a print completion notification sent from the corresponding printer to the client 30 .
  • the client 30 is enabled to perform direct communication (information acquisition, function setting) with the printer (B) while making the printer (B) perform printing through the server 40 .
  • Modules in which the present invention is realized and related data may also be loaded into the host computer 10 from the memory medium reader 1050 of the host computer 10 .
  • the modules in which the present invention is realized and the related data may be recorded on the memory medium 1060 shown in FIG. 9 and may have a configuration 400 shown in FIG. 10 . In such a case, the modules in which the present invention is realized and the related data can be loaded into the host computer 10 through the memory medium reader 1050 shown in FIG. 9 .
  • FIG. 11 shows a memory map 300 showing the modules and data loaded into the RAM in the memory section 1030 of the host computer 10 to be executed or used in accordance with the present invention.
  • the arrangement may be such that the modules in which the present invention is realized and related data, which are recorded on the memory medium 1060 shown in FIG. 9 , are temporarily stored (installed) in the disk unit or the like in the memory section 1030 of the host computer 10 , and are loaded from the disk unit into the RAM in the memory section 1030 of the host computer 10 when they are executed or used.
  • the present invention may be completed in such a manner that a system or an apparatus is supplied with a memory medium on which program codes of a software for realizing the functions of each embodiment are recorded, and a computer (or a central processing unit (CPU) or a microprocessor unit (MPU)) provided in the system or the apparatus reads out and executes the program codes stored on the memory medium.
  • a computer or a central processing unit (CPU) or a microprocessor unit (MPU)
  • the program codes themselves read out from the memory medium realize the above-described functions of each embodiment, and the memory medium on which the program codes are recorded constitutes the present invention.
  • the present invention comprises not only realizing the above-described functions of each embodiment by executing the program codes read out by the computer but also a method in which the OS, etc., running on the computer perform part or the whole of actual processing according to instructions provided by the program codes, and in which the above-described functions of each embodiment are realized by the processing.
  • the present invention also comprises a method in which the program codes read out from the memory medium are written to a memory provided in a function expansion board inserted in the computer or a function expansion unit connected to the computer, and in which a CPU or the like provided in the function expansion board or function expansion unit operates to perform part or the whole of actual processing according to instructions provided by the program codes, thereby realizing the above-described functions of each embodiment.
  • the host unit in accordance with the present invention outputs to the print output apparatus a first command to make the print output apparatus execute shift processing for shifting from the sleep mode to the standby mode, and outputs the print data to the print output apparatus after outputting the first command. Therefore the print output apparatus can execute processing for shifting to the standby state before transmission of the print data. As a result, the speed of printing started when the print output apparatus is in the sleep state can be effectively increased.
  • the host unit in accordance with the present invention outputs to the print output apparatus a second command for stopping calibration processing before outputting the print data, thereby inhibiting unnecessary calibration processing in the case of B/W output. Therefore the print output apparatus can immediately execute printing. Consequently, the speed of printing started when the print output apparatus is in the sleep state can be effectively increased.
  • the print output apparatus in accordance with the present invention performs processing for shifting from the sleep mode to the standby mode when it receives the first command issued from the host unit while it is in the sleep mode before reception of the print data. Therefore the print output apparatus can execute processing for shifting to the standby state before receiving the print data. Consequently, the speed of printing started when the print output apparatus is in the sleep state can be effectively increased.
  • the print output apparatus in accordance with the present invention enters the standby mode by stopping calibration processing when receiving the second command issued from the host unit. Therefore, when the print output apparatus outputs a B/W print, it does not perform unnecessary calibration processing and can immediately execute printing. Consequently, the speed of printing started when the print output apparatus is in the sleep state can be effectively increased.
  • preparation and transfer of the print data on the host unit side and processing for shifting from the sleep mode to the standby mode on the print output apparatus side are performed in parallel with each other, so that the print output apparatus can execute shift processing before transmission of the print data.
  • the host unit outputs to the print output apparatus the first command to make the print output apparatus execute processing for shifting from the sleep mode to the standby mode, and outputs the print data to the print output apparatus after outputting the first command
  • the print output apparatus performs processing for shifting from the sleep mode to the standby mode when it receives the first command issued from the host unit while it is in the sleep mode before reception of the print data. Therefore the print output apparatus can execute processing for shifting to the standby state before transmission of the print data. Consequently, the speed of printing started when the print output apparatus is in the sleep state can be effectively increased.
  • the host unit outputs to the print output apparatus the second command for stopping calibration processing executed in shift processing before outputting the print data in the case of B/W output, and the print output apparatus enters the standby mode by stopping calibration processing executed in shift processing when receiving the second command issued from the host unit, thus inhibiting unnecessary calibration processing in the case of B/W output. Therefore the print output apparatus can immediately execute printing. Consequently, the speed of printing started when the print output apparatus is in the sleep state can be effectively increased.

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